Wireless communication system and method using grouping maximum likelihood detection

ABSTRACT

Disclosed is a method for increasing a data transfer rate without an increase in the whole bandwidth using intrinsic spreading codes and orthogonal codes. The method uses interleaving, OFDM modulation/demodulation, and maximum likelihood detection (MLD) to overcome the effects of multipath fading or signal interference, determines grouped optimal values by a grouping method of dividing the intrinsic spreading codes in series, and calculates an integrated optimal value for all the intrinsic spreading codes using the grouped optimal values, thereby reducing the complexity of MLD according to the length of the intrinsic spreading code and acquiring an improved performance.

CROSS REFERENCE TO RELATED APPLICATION

This application is based on Korea Patent Application No. 2002-83746filed on Dec. 24, 2002 in the Korean Intellectual Property Office, thecontent of which is incorporated herein by reference.

BACKGROUND OF THE INVENTION

(a) Field of the Invention

The present invention relates to a system and method for reducing theeffects of multi-path fading and signal interference in a system usingorthogonal codes and binary signal values. More specifically, thepresent invention relates to a maximum likelihood detection (MLD) systemand method that reduces the complexity of MLD and improves performancein the system using orthogonal codes and binary signal values.

(b) Description of the Related Art

The modulation/demodulation methods for supporting a data transfer rateincreasing in a confined frequency band include the quadrature amplitudemodulation (QAM) method. The QAM modulation method may enhance the datatransfer rate because the amount of information increases with anincrease in the constellation, but it has a problem in regard to itsmobility and application for 16-QAM or greater with a separation of morethan a predetermined value. Namely, the QAM method is susceptible to theeffect of distortion because the redundancy of noise decreases with anincrease in the constellation. That is, the QAM modulation method has atrade-off relationship between information and noise.

It is known that the channel capacity of channels having a richscattering characteristic is proportional to the number of transceiverantennas in the same bandwidth. Hence, studies have been done on amethod for detecting received signals using a multiple input/multipleoutput (MIMO) antenna system with a plurality of antennas so as toincrease channel capacity. But this method is known to have a problem inregard to its implementation, because the mobile terminal concerned isrequired to have a plurality of antennas and a rich scatteringcharacteristic for channels.

In addition, there has been recently suggested a method for increasingdata transfer rate without an increase in the entire bandwidth for usersby using an intrinsic spreading code and orthogonal codes. But thismethod, which utilizes binary values, has problems in regard toovercoming the effects of multipath fading or signal interference andthe complexity of MLD calculations according to the length of thespreading code.

SUMMARY OF THE INVENTION

It is an advantage of the present invention to solve the problems withprior art and to provide a system and method for overcoming the effectsof multipath fading or signal interference that is taken intoconsideration in the multipath environment.

It is another advantage of the present invention to reduce thecomplexity of calculations according to the length of the intrinsicspreading code in MLD and to improve the performance, thereby reducingthe complexity in the system implementation.

In one aspect of the present invention, there is provided a wirelesscommunication system that includes: a transmitter including anorthogonal encoder for converting serially input binary signals toparallel binary signals and orthogonally encoding the parallel binarysignals, a first multiplier for multiplying the orthogonally encodedbinary signals by an intrinsic spreading code to spread the orthogonallyencoded binary signals, and an OFDM (Orthogonal Frequency DivisionMultiplexing) modulator for OFDM-modulating the spread signals; and areceiver including an OFDM demodulator for demodulating theOFDM-modulated signals, and a maximum likelihood detector for performinga maximum likelihood detection of the demodulated spread signals.

The maximum likelihood detector groups the OFDM-demodulated signals intoa predetermined number of blocks to perform the maximum likelihooddetection, and uses the grouped maximum likelihood detection values toperform a whole maximum likelihood detection.

The transmitter of the wireless communication system further includes: afirst serial-to-parallel converter for serial-to-parallel converting thesignals spread with the intrinsic spreading code; and an interleaver forinterleaving the serial-to-parallel converted signals and sending theinterleaved signals to the OFDM modulator. The receiver furtherincludes: a deinterleaver for deinterleaving the OFDM-demodulatedsignals; and a first parallel-to-serial converter for parallel-to-serialconverting the deinterleaved signals and sending the parallel-to-serialconverted signals to the maximum likelihood detector.

The maximum likelihood detector includes: a second multiplier formultiplying the OFDM-demodulated signals by the intrinsic spreadingcode; a grouping section for grouping the multiplied signals intoblocks; a grouping maximum approximation detector for performing amaximum likelihood detection of the grouped blocks; an integratedmaximum approximation detector for performing a whole maximum likelihooddetection based on the grouped maximum approximation values; anorthogonal despreader for orthogonally despreading a sequence having amaximum approximation value to output parallel signals; and a secondparallel-to-serial converter for converting the parallel output signalsto serial signals.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of the specification, illustrate an embodiment of the invention,and, together with the description, serve to explain the principles ofthe invention:

FIG. 1 is a block diagram of a wireless communication system accordingto an embodiment of the present invention;

FIG. 2 is a detailed block diagram of a grouping maximum likelihooddetector according to an embodiment of the present invention; and

FIG. 3 is a signal diagram showing the multiplication of orthogonalcodes and intrinsic spreading codes.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the following detailed description, only the preferred embodiment ofthe invention has been shown and described, simply by way ofillustration of the best mode contemplated by the inventor(s) ofcarrying out the invention. As will be realized, the invention iscapable of modification in various obvious respects, all withoutdeparting from the invention. Accordingly, the drawings and descriptionare to be regarded as illustrative in nature, and not restrictive.

For an evident description of the present invention, the parts notrelated to the description are omitted in the illustrations. The samereference numerals are assigned to the same parts all through thespecification.

Hereinafter, the embodiment of the present invention will be describedin detail with reference to the accompanying drawings.

FIG. 1 is a block diagram of a wireless communication system accordingto the embodiment of the present invention.

The wireless communication system according to the embodiment of thepresent invention comprises a transmitter that includes a singleorthogonal code (hereinafter referred to as “TOC”) block 100 including aserial-to-parallel converter 101, and an orthogonalizer using first tofourth orthogonal codes (hereinafter expressed as “Sub-w(1,2,3,4)”), aserial-to-parallel converter 110, an interleaver 120, and an OFDMmodulator 130; and a receiver that includes an OFDM demodulator 200, adeinterleaver 210, a parallel-to-serial converter 220, and a groupingmaximum likelihood detector 230. Here, the configuration shown in theTOC block corresponds to the basic structure of the prior art forincreasing channel capacity using orthogonal codes and binary signals.

The TOC block 100 orthogonalizes serially input binary signals using thefirst to fourth Sub-w(1,2,3,4). The orthogonalized binary signals aresummated, multiplied by an intrinsic spreading code W1, and sent to theserial-to-parallel converter 110. The parallel bit streams output fromthe serial-to-parallel converter 110 are interleaved from theinterleaver 120. The interleaved bit streams are fed into the OFDMmodulator 130 for OFDM modulation. The modulated signals are sentthrough OFDM channels. The individual signal waveforms of the OFDMchannels are present at a point where the power of the channels of adifferent channel center frequency approaches zero, so they cause nointerference even when they are overlapped.

The OFDM modulated signals transferred on a plurality of carriersthrough the OFDM channels are demodulated from the OFDM demodulator 200.The demodulated signals are deinterleaved from the deinterleaver 21,converted to serial bit streams via the parallel-to-serial converter220, and sent to the grouping maximum likelihood detector 230. Thegrouping maximum likelihood detector 230 performs MLD in the manner ofthe method that will be described later according to the embodiment ofthe present invention.

First, the entire signal processing procedures of the present inventionsystem will be described in detail by way of the following example.

Input data are sent to the TOC block 100 using orthogonal codes toincrease channel capacity, and to the serial-to-parallel converter 110through an intrinsic spreading code.

It is assumed that the binary signals output from the serial-to-parallelconverter 110 are d(1)=(d, −d, d, d), where d represents the minimumdistance of the constellation. The orthogonal codes, the intrinsicspreading code and the binary signal data can be used in the followingdescription, where the binary signal data 0 and 1 are respectivelydenoted as “−” and “+” in the orthogonal codes and the intrinsicspreading code.

Hence, the first to fourth orthogonal codes are expressed as follows:Sub-w(1)=(1 1 1 1)→(+ + + +)Sub-w(2)=(1 0 1 0)→(+ − + −)Sub-w(3)=(1 1 0 0)→(+ + − −)Sub-w(4)=(1 0 0 1)→(+ − − +)

The intrinsic spreading code, W1=(0 1 0 1 0 1 0 1) is expressed by (− +− + − + − +).

If considering d as a constant, the input data binary signals d(1)=(d,−d, d, d) from the serial-to-parallel converter 110 can be expressed byd(1)=(+1 −1 +1 +1).

Each of the first to fourth orthogonal codes Sub-w(1), Sub-w(2),Sub-w(3) and Sub-w(4) is multiplied by the binary signal d(1) to produceoutput code C as follows:C(1)=(+1 +1 +1 +1)C(2)=(−1 +1 −1 +1)C(3)=(+1 +1 −1 −1)C(4)=(+1 −1 −1 +1).

These output codes are summated to give S=(+2 +2 −2 +2).

The summated value S is multiplied by the intrinsic spreading code W1 togive spread data SD=(−2 +2 −2 +2 +2 −2 −2 +2).

The spread code values are the output values before theserial-to-parallel converter 110. The serial-to-parallel convertedsignals are fed into the interleaver 120, and the output of theinterleaver 120 through the spread data SD is transferred via the OFDMmodulator 130. The OFDM modulator 130 generally comprises an IFFT(Inverse Fast Fourier Transform) section, a parallel-to-serialconverter, a guard interval inserter, and a carrier (RF) section, noneof which are shown. The input binary spread code value SC can be outputthrough the internal processing of the OFDM modulator 130.

Now, a process for demodulating the channel-passed input data anddemapping the demodulated data into the original signals will bedescribed in detail.

The data received through the OFDM channels are fed into thedeinterleaver 210 via the OFDM demodulator 200. The OFDM demodulator 200generally includes the functions of multiplying the noise-mixed inputsignals by the carrier (RF), removing an RF component via a low-passfilter (LPF), performing an A/D conversion, removing the guard interval,and performing an FFT, which functions are not shown.

The deinterleaver 210 performs the reverse process of the interleaver ofthe transmitter and outputs the deinterleaved data to theparallel-to-serial converter 230. After the parallel-to-serialconversion, the signal values are output as optimized values through agrouping MLD.

The spread data SD=(−2 +2 −2 +2 +2 −2 −2 +2) are multiplied by theintrinsic spreading code W1 through a multiplier. The intrinsicspreading code W1 has the same value of the intrinsic spreading codeW1=(0 1 0 1 0 1 0 1) of the transmitter and is expressed by (−+−+−+−+).

The individual values of the spread data are multiplied by the intrinsicspreading code W1 to output a value of (+2 +2 +2 +2 −2 −2 +2 +2).

The output value is revised through the grouping MLD and then fed intoan orthogonal despreader 234.

The data fed into the orthogonal despreader 234 are multiplied by thefirst to fourth orthogonal codes Sub-w(1) to (4) to give the followingvalues:(+2+2+2+2−2−2+2+2)(−2−2+2+2−2−2−2−2)(+2+2+2+2+2+2−2−2)(+2+2−2−2+2+2+2+2)

The individual values are integrated for one period and multiplied bythe value of one period (e.g., one period of W1 is 8) to give (1, −1, 1,1), which is then multiplied by d. The restored values (d, −d, d, d) areparallel-to-serial converted into the original values.

Next, the grouping MLD process according to the embodiment of thepresent invention will be described in detail with reference to FIG. 2.

FIG. 2 is a block diagram of the grouping maximum likelihood detector.The grouping maximum likelihood detector comprises, as shown in FIG. 2,a multiplier for multiplying an input signal by the intrinsic spreadingcode W1, a grouping maximum approximation detection processor 232, anintegrated maximum approximation detection processor 233, a deorthogonalspreader 234, and a parallel-to-serial converter 235.

Next, the operations of the grouping maximum approximation detectionprocessor 232 and the integrated maximum approximation detectionprocessor 233 shown in FIG. 2 will be described by way of the specificequations.

The input signals from the OFDM demodulator 200, the deinterleaver 210,and the parallel-to-serial converter 220 are fed into the groupingmaximum approximation detection processor 232. The input signals aremultiplied by the intrinsic spreading code W1 and then grouped by agrouping section 231.

In the grouping step, the individual bit interval information of thefirst to fourth orthogonal codes Sub-w(1) to (4) are summated and thenmultiplied by the intrinsic spreading code W1. The multiplication valueis then divided by the bit interval of Sub-w(1,2,3,4) to determine theinterval of the intrinsic spreading code. When the interval of theintrinsic spreading code is 8 and the Sub-w(1,2,3,4) is a 4-bitinterval, each group after grouping has an interval of 2.

After grouping, the received signals R_(k1), R_(k2), . . . , R_(kl-1)and R_(kl) are subjected to noise and Rayleigh fading. Thus the signalR_(kl) represented by k vectors can be given by the following equation:R_(kl)=H_(k1)S_(kl) ^(T)+N  [Equation 1]where the diagonal matrix H_(k1) is the Rayleigh fading constant of asub carrier allocated to the grouped block; S_(kl) ^(T) is thetransposed value of the transmitted sequence; and N is the noise vector.

The grouping maximum approximation detection processor 233 performs MLDfor R_(kl). In the MLD, the transmitted sequence is selected thatminimizes the Euclidean distance e_(j) ² among all the availabletransmitted and received sequences.

Let the set of all the transmittable sequences be V_(jl) (j=1, . . . ,2^(Nw/Sw)), then the Euclidean distance e_(j) ² can be calculated fromthe following equation:e_(j) ²=min|R_(kl)−H_(k)V_(jl) ^(T)|²  [Equation 2]

The most approximating transmitted sequence V_(jl)=S′_(kl) is selectedwhen the Euclidean distance is at a minimum. Following the maximumapproximation detection processing for k blocks, where k is the bitlength of each Sub-w(1,2,3,4), the maximum likelihood value processedfrom the integrated maximum approximation processor 233 is used toperform the optimized MLD for integrated R_(kl) blocks.

The conventional MLD algorithm, which uses the fading constant matrixH_(kl), requires channel information for assigning a weight to all thetransmitted sequences V_(jl), so its complexity increases at a ratio ofgeometrical progression with an increase in the length of the sequenceand a decrease in the Euclidean distance. Contrarily, the embodiment ofthe present invention groups all the user signals from the transmitterinto blocks in the units of bit of the orthogonal code Sub-w(1,2,3,4)multiplied by the spreading code W1 allocated to the users. According tothe embodiment of the present invention, 2^(Nw/Sw) available sequencesare detected from the MLD rather than k sequences, where Nw is theinterval length of the intrinsic spreading code W1; and Sw is the bitinterval length of each orthogonal code. Namely, as many transmittedsignals as the length of the intrinsic spreading code, Nw, are groupedinto blocks in the units of bit of each Sub-w(1,2,3,4) so as to reducethe complexity of MLD. Let the code length of each Sub-w(1,2,3,4) be Sw,then the transmitted signals are grouped into Sw blocks. The partiallyspread block in each unit bit has the maximum approximations of2^(Nw/Sw) partially spread code bits for each partially spread code bit.During transmission, the data bits d_(il), each of which is spread bythe orthogonal codes Sub-w(1,2,3,4), are spread by 2^(Nw/Sw) partiallyspread code vectors.

The codes used for spreading are orthogonal Walsh-Hadamard codes andhave the cross-correlation of zero. For the spread chip stream of thek-th block Sk having a length of Nw/Sw can be expressed by the followingequation:

$\begin{matrix}{S_{k} = {{\underset{i = {{\frac{Nw}{Sw}k} + 1}}{\sum\limits^{\frac{Nw}{Sw}{({k + 1})}}}{{Sub}_{{({1,2,3,4})},k}C_{i}}} = \left\lbrack {s_{0,k},s_{1,k},\ldots\mspace{14mu},s_{{({\frac{Nw}{Sw} - 1})},k}} \right\rbrack}} & \left\lbrack {{Equation}\mspace{11mu} 3} \right\rbrack\end{matrix}$where C is the intrinsic spreading code.

The orthogonal despreader 235 uses the Sub-w(1,2,3,4) codes to despreadthe received signals spread with the Sub-w(1,2,3,4) codes and subjectedto the grouping MLD process, and divides the resulting value of thedespreading by the length of the intrinsic spreading code, Nw to obtaindata values received from the transmitter. The data values are processedat the parallel-to-serial converter 235 into finally received data.

FIG. 3 shows an example of the multiplication of the orthogonal code bythe intrinsic spreading code.

To simplify the description of the grouping process that involves themultiplication of the orthogonal code Sub-w(1,2,3,4) by the intrinsicspreading code W1, the lengths of the intrinsic spreading code W1 andthe orthogonal code are set to 8 and 4, respectively. Actually, theintrinsic spreading code has a considerably large length.

In FIG. 3, signal 3A shows the 2-fold expanded bit interval of one codeof Sub-w(1,2,3,4); signal 3B is the intrinsic spreading code W1; andsignal 3C shows the multiplication of the intrinsic spreading code andthe Sub-w(1,2,3,4), where Nw is 8, Sw is 4, and Nw/Sw is 2. The bitinterval length of Sub-w(1,2,3,4) is 4, so the length of the intrinsicspreading code Nw is grouped into 4 blocks. Namely, the interval lengthof the grouped blocks is 2. Expediently, a short code length has beenexemplified in this description, but it must be taken into considerationthat the length of the intrinsic spreading code is considerably large.

While this invention has been described in connection with what ispresently considered to be the most practical and preferred embodiment,it is to be understood that the invention is not limited to thedisclosed embodiments, but, on the contrary, is intended to covervarious modifications and equivalent arrangements included within thespirit and scope of the appended claims.

The present invention uses the intrinsic spreading code and theorthogonal codes to increase the data transfer rate without an increasein the whole bandwidth allocated for users, and performs a grouping MLDaccording to the configuration of the present invention to remarkablyreduce the complexity of the MLD system and improve the performance.

1. A wireless communication system comprising: a transmitter includingan orthogonal encoder for converting serially input binary signals toparallel binary signals and orthogonally encoding the parallel binarysignals, a first multiplier for multiplying the orthogonally encodedbinary signals by an intrinsic spreading code to spread the orthogonallyencoded binary signals, and an OFDM (Orthogonal Frequency DivisionMultiplexing) modulator for OFDM-modulating the spread signals; and areceiver including an OFDM demodulator for demodulating theOFDM-modulated signals, and a maximum likelihood detector for performinga maximum likelihood detection of the demodulated spread signals, themaximum likelihood detector grouping the OFDM-demodulated signals into apredetermined number of blocks, and performing maximum likelihooddetection for each of the blocks to get a predetermined number ofmaximum likelihood detection values, and performing maximum likelihooddetection for all of the predetermined number of maximum likelihooddetection values.
 2. The wireless communication system as claimed inclaim 1, wherein the transmitter further includes: a firstserial-to-parallel converter for serial-to-parallel converting thesignals spread with the intrinsic spreading code; and an interleaver forinterleaving the serial-to-parallel converted signals and sending theinterleaved signals to the OFDM modulator, the receiver furtherincluding: a deinterleaver for deinterleaving the OFDM-demodulatedsignals; and a first parallel-to-serial converter for parallel-to-serialconverting the deinterleaved signals and sending the parallel-to-serialconverted signals to the maximum likelihood detector.
 3. The wirelesscommunication system as claimed in claim 1, wherein the maximumlikelihood detector comprises: a second multiplier for multiplying theOFDM-demodulated signals by the intrinsic spreading code; a groupingsection for grouping the multiplied signals into the predeterminednumber of blocks; a grouping maximum approximation detector forperforming a maximum likelihood detection for each of the blocks to getthe predetermined number of maximum likelihood detection values; anintegrated maximum approximation detector for performing maximumlikelihood detection for the predetermined number of maximum likelihooddetection values; an orthogonal despreader for orthogonally despreadinga sequence having a maximum approximation value to output parallelsignals; and a second parallel-to-serial converter for converting theparallel output signals to serial signals.
 4. The wireless communicationsystem as claimed in claim 3, wherein the grouping section groups aninterval length of the intrinsic spreading code into blocks having a bitinterval length of the orthogonal code.
 5. A wireless communicationmethod comprising: orthogonally encoding serial binary signals;multiplying the orthogonally encoded serial binary signals by anintrinsic spreading code to spread the orthogonally encoded binarysignals; OFDM-modulating the spread signals; OFDM-demodulating theOFDM-modulated signals: grouping the demodulated signals into apredetermined number of blocks; performing maximum likelihood detectionfor each of the predetermined number of blocks to get a predeterminednumber of maximum likelihood detection values; and performing maximumlikelihood detection for all of the predetermined number of maximumlikelihood detection values.
 6. The wireless communication method asclaimed in claim 5, further comprising: serial-to-parallel convertingthe signals spread with the intrinsic spreading code, and interleavingthe serial-to-parallel converted signals; and deinterleaving theOFDM-demodulated signals; and parallel-to-serial converting thedeinterleaved signals and sending the parallel-to-serial convertedsignals to a maximum likelihood detector.
 7. The wireless communicationmethod as claimed in claim 6, wherein said grouping the demodulatedsignals further comprises multiplying the OFDM-demodulated signals bythe intrinsic spreading code, grouping the multiplied signals into thepredetermined number of blocks.
 8. The wireless communication method asclaimed in claim 7, wherein the grouping comprises grouping an intervallength of the intrinsic spreading code into the blocks having a bitinterval length of the orthogonal code.
 9. A wireless communicationtransmitter, comprising: an orthogonal encoder to convert serially inputbinary signals into a first number of parallel binary signals and toorthogonally encode the binary signals; and an OFDM (OrthogonalFrequency Division Multiplexing) modulator to OFDM-modulate the spreadsignals, wherein the OFDM-modulated signals are transmitted such that areceiver to receive the OFDM-modulated signals is configured todemodulate the OFDM-modulated signals and to perform a maximumlikelihood detection by grouping the OFDM-demodulated signals into asecond number of blocks, performing grouped maximum likelihood detectionfor each block to determine grouped maximum likelihood detection values,and performing integrated maximum likelihood detection to determine anintegrated maximum likelihood detection value.
 10. The wirelesscommunication transmitter of claim 9, further comprising: an interleaverto interleave the binary signals and to send the interleaved signals tothe OFDM modulator.
 11. The wireless communication transmitter of claim9, wherein the first number of parallel binary signals is the samenumber as the second number of blocks.
 12. A method for wirelesscommunication transmission, comprising: converting serially input binarysignals into a first number of parallel binary signals; orthogonallyencoding the binary signals; OFDM (Orthogonal Frequency DivisionMultiplexing)-modulating the binary signals; and transmitting theOFDM-modulated signals, wherein a receiver to receive the OFDM-modulatedsignals is configured to demodulate the OFDM-modulated signals and toperform a maximum likelihood detection by grouping the OFDM-demodulatedsignals into a second number of blocks, performing grouped maximumlikelihood detection for each block to determine grouped maximumlikelihood detection values, and performing integrated maximumlikelihood detection to determine an integrated maximum likelihooddetection value.
 13. The method of claim 12, further comprising:interleaving the binary signals.
 14. The method of claim 12, wherein thefirst number of parallel binary signals is the same number as the secondnumber of blocks.
 15. A wireless communication receiver to receiveOFDM-modulated signals, comprising: an OFDM (Orthogonal FrequencyDivision Multiplexing) demodulator to demodulate the OFDM-modulatedsignals; and a maximum likelihood detector to perform a maximumlikelihood detection of the OFDM-demodulated signals, wherein themaximum likelihood detector groups the OFDM-demodulated signals into afirst number of blocks, performs grouped maximum likelihood detectionfor each block to determine grouped maximum likelihood detection values,and performs integrated maximum likelihood detection to determine anintegrated maximum likelihood detection value.
 16. The wirelesscommunication receiver of claim 15, wherein the receiver furthercomprises: a deinterleaver to deinterleave the OFDM-demodulated signals.17. The wireless communication receiver of claim 15, wherein the firstnumber of blocks corresponds to a second number of parallel binarysignals orthogonally encoded by a transmitter configured to transmit theOFDM-modulated signals.
 18. The wireless communication receiver of claim15, wherein the maximum likelihood detector comprises: a groupingsection to group the OFDM-demodulated signals into the first number ofblocks; a grouping maximum approximation detector to perform the groupedmaximum likelihood detection for each block to determine the groupedmaximum likelihood detection values; an integrated maximum approximationdetector to perform the integrated maximum likelihood detection todetermine the integrated maximum likelihood detection value; anorthogonal despreader to orthogonally despread a sequence having amaximum approximation value, and to output parallel signals; and aparallel-to-serial converter to convert the parallel output signals toserial signals.
 19. A method for wireless communication reception,comprising: receiving OFDM (Orthogonal Frequency DivisionMultiplexing)-modulated signals; OFDM-demodulating the OFDM-modulatedsignals: grouping the OFDM-demodulated signals into a first number ofblocks; performing grouped maximum likelihood detection for each of thefirst number of blocks to determine grouped maximum likelihood detectionvalues; and performing integrated maximum likelihood detection todetermine an integrated maximum likelihood detection value.
 20. Themethod of claim 19, further comprising: deinterleaving theOFDM-demodulated signals.
 21. The method of claim 19, wherein the firstnumber of blocks corresponds to a second number of parallel binarysignals orthogonally encoded by a transmitter configured to transmit theOFDM-modulated signals.